Öz
Taylor-Couette flow between two concentric cylinders has received much attention due to its use in various applications, including biomedical devices, micro electro-mechanical systems, polymer pumping and electric motor cooling. Due to the complex interaction of the viscosity and the involved geometry within the confined space, different flow regimes are dominant under different conditions, affecting the fluid dynamics and heat transfer. In analyzing the mentioned flow, besides the experimental and computational studies, analytical models have been developed with varying levels of complication. In the present study, using the homotopy of both the flow and the domain geometry between the concentric and eccentric cylinders, a practical formula for flow between eccentric cylinders is developed. In doing so, an appropriate transformation function for the geometry is developed and embedded into the velocity equation for the concentric cylinders. The resultant equation is tested against flow simulation results. A validity margin analysis is performed based on the variation of the mass flow rate between the cylinders. It is seen that the proposed model for eccentric cylinders is applicable for all gap distances, unlike the previous models that are restricted to narrow gaps. Finally, a separate formula to quantify the error in the estimates of the present method is also derived, which involves the ratio of the cylinders and the eccentricity.
Anahtar Kelimeler
Taylor-Couette flow Homotopy Laminar flow Navier-Stokes Eccentric cylinders
Teşekkür
The authors would like to thank Ses3000, Ltd. in Izmir, TURKEY, for their support of this study.
Kaynakça
- [1] Fénot M, Bertin Y, Dorignac E, Lalizel G. A review of heat transfer between concentric rotating cylinders with or without axial flow. Int J Therm Sci, 2011; 50: 1138-1155. [2] Wen J, Zhang WY, Ren LZ, Bao LY, Dini D, Xi HD, Hu HB. Controlling the number of vortices and torque in Taylor-Couette flow. J Fluid Mech 2020; 901: A30.
- [3] Deutsch S, Tarbell JM, Manning KB, Rosenberg G, Fontaine AA. Experimental fluid mechanics of pulsatile artificial blood pumps. Annu Rev Fluid Mech, 2006; 38: 65-86.
- [4] Goubergrits L, Osman J, Mevert R, Kertzscher U, Pöthkow K, Hege HC. Turbulence in blood damage modeling. Int J Artif Organs, 2016; 39(4): 160-165.
- [5] Hammond TG, Hammond JM. Optimized suspension culture: The rotating-wall vessel. Am J Physiol-Renal, 2001; 281: F12-F25.
- [6] Lim DH, Lee MY, Lee HS, Kim SC. Performance evaluation of an in-wheel motor cooling system in an electric vehicle/hybrid electric vehicle. Energies, 2014; 7: 961-971.
- [7] Li H. Cooling of a permanent magnet electric motor with a centrifugal impeller. Int J Heat Mass Tran, 2010; 53: 797-810.
- [8] Abe Y, Ishii K, Isoyama T, Saito I, Inoue Y, Ono T, Nakagawa H, Nakano E, Fukazawa K, Ishihara K, Fukunaga K, Ono M, Imachi K. The helical flow pump with a hydrodynamics levitation impeller. J Artif Organs, 2012; 15: 331-340.
- [9] Mukunda PG, Shailesh RA, Kiran AS, Shrikantha SR. Experimental studies of flow patterns of different fluids in a partially filled rotating cylinder. J Appl Fluid Mech, 2009; 2(1): 39-43.
- [10] Lebiga VA, Pak AY, Zinoyev VN, Mironov DS, Medvedev AE. Simulation of Couette flow in semicircular channel. AIP Conf Proceed, 2019; 030017.
- [11] Diprima RC, Stuart JT. Flow between Eccentric Rotating Cylinders. J Lubric Tech, 1971; 72-Lub-J.
- [12] Saatdjian E, Midoux N. Flow of a Newtonian fluid between eccentric rotating cylinders. Int J Numer Meth Heat Fluid Fl, 1992; 2: 261-270.
- [13] Teleszewski TJ. Effect of viscous dissipation in Stokes flow between rotating cylinders using BEM. Int J Numer Meth Heat Fluid Fl, 2020; 30(4): 2121-2136.
- [14] Faghih MM, Sharp MK. Evaluation of energy dissipation rate as a predictor of mechanical blood damage. Artif Organs, 2018; 43: 666-676.
- [15] Mohith S, Karanth PN, Kulkarni SM. Recent trends in mechanical micropumps and their applications: A review. Mechatronics, 2019; 60: 34-55.
- [16] Dai RX, Dong Q, Szeri AZ. Flow between Eccentric Rotating Cylinders: Bifurcation and Stability. Int J Eng Sci, 1992; 30(10): 1323-1340.
Öz
Taylor-Couette flow between two concentric cylinders has received much attention due to its use in various applications, including biomedical devices, micro electro-mechanical systems, polymer pumping and electric motor cooling. Due to the complex interaction of the viscosity and the involved geometry within the confined space, different flow regimes are dominant under different conditions, affecting the fluid dynamics and heat transfer. In analyzing the mentioned flow, besides the experimental and computational studies, analytical models have been developed with varying levels of complication. In the present study, using the homotopy of both the flow and the domain geometry between the concentric and eccentric cylinders, a practical formula for flow between eccentric cylinders is developed. In doing so, an appropriate transformation function for the geometry is developed and embedded into the velocity equation for the concentric cylinders. The resultant equation is tested against flow simulation results. A validity margin analysis is performed based on the variation of the mass flow rate between the cylinders. It is seen that the proposed model for eccentric cylinders is applicable for all gap distances, unlike the previous models that are restricted to narrow gaps. Finally, a separate formula to quantify the error in the estimates of the present method is also derived, which involves the ratio of the cylinders and the eccentricity.
Anahtar Kelimeler
Taylor-Couette flow Homotopy Laminar flow Navier-Stokes Eccentric cylinders
Kaynakça
- [1] Fénot M, Bertin Y, Dorignac E, Lalizel G. A review of heat transfer between concentric rotating cylinders with or without axial flow. Int J Therm Sci, 2011; 50: 1138-1155. [2] Wen J, Zhang WY, Ren LZ, Bao LY, Dini D, Xi HD, Hu HB. Controlling the number of vortices and torque in Taylor-Couette flow. J Fluid Mech 2020; 901: A30.
- [3] Deutsch S, Tarbell JM, Manning KB, Rosenberg G, Fontaine AA. Experimental fluid mechanics of pulsatile artificial blood pumps. Annu Rev Fluid Mech, 2006; 38: 65-86.
- [4] Goubergrits L, Osman J, Mevert R, Kertzscher U, Pöthkow K, Hege HC. Turbulence in blood damage modeling. Int J Artif Organs, 2016; 39(4): 160-165.
- [5] Hammond TG, Hammond JM. Optimized suspension culture: The rotating-wall vessel. Am J Physiol-Renal, 2001; 281: F12-F25.
- [6] Lim DH, Lee MY, Lee HS, Kim SC. Performance evaluation of an in-wheel motor cooling system in an electric vehicle/hybrid electric vehicle. Energies, 2014; 7: 961-971.
- [7] Li H. Cooling of a permanent magnet electric motor with a centrifugal impeller. Int J Heat Mass Tran, 2010; 53: 797-810.
- [8] Abe Y, Ishii K, Isoyama T, Saito I, Inoue Y, Ono T, Nakagawa H, Nakano E, Fukazawa K, Ishihara K, Fukunaga K, Ono M, Imachi K. The helical flow pump with a hydrodynamics levitation impeller. J Artif Organs, 2012; 15: 331-340.
- [9] Mukunda PG, Shailesh RA, Kiran AS, Shrikantha SR. Experimental studies of flow patterns of different fluids in a partially filled rotating cylinder. J Appl Fluid Mech, 2009; 2(1): 39-43.
- [10] Lebiga VA, Pak AY, Zinoyev VN, Mironov DS, Medvedev AE. Simulation of Couette flow in semicircular channel. AIP Conf Proceed, 2019; 030017.
- [11] Diprima RC, Stuart JT. Flow between Eccentric Rotating Cylinders. J Lubric Tech, 1971; 72-Lub-J.
- [12] Saatdjian E, Midoux N. Flow of a Newtonian fluid between eccentric rotating cylinders. Int J Numer Meth Heat Fluid Fl, 1992; 2: 261-270.
- [13] Teleszewski TJ. Effect of viscous dissipation in Stokes flow between rotating cylinders using BEM. Int J Numer Meth Heat Fluid Fl, 2020; 30(4): 2121-2136.
- [14] Faghih MM, Sharp MK. Evaluation of energy dissipation rate as a predictor of mechanical blood damage. Artif Organs, 2018; 43: 666-676.
- [15] Mohith S, Karanth PN, Kulkarni SM. Recent trends in mechanical micropumps and their applications: A review. Mechatronics, 2019; 60: 34-55.
- [16] Dai RX, Dong Q, Szeri AZ. Flow between Eccentric Rotating Cylinders: Bifurcation and Stability. Int J Eng Sci, 1992; 30(10): 1323-1340.
Ayrıntılar
| Birincil Dil | İngilizce |
|---|---|
| Konular | Mühendislik |
| Bölüm | Makaleler |
| Yazarlar | |
| Yayımlanma Tarihi | 28 Şubat 2023 |
| Yayımlandığı Sayı | Yıl 2023 Cilt: 11 Sayı: 1 |